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Keita KODAMA, Takamichi SHIMIZU, Takashi YAMAKAWA and Ichiro AOKI reporter: 黃薇蓉

Reproductive biology of the female Japanese mantis Shrimp Oratosquilla oratoria (Stomatopoda) in relation to changes in the seasonal pattern of larval occurrence in Tokyo Bay, Japan. Keita KODAMA, Takamichi SHIMIZU, Takashi YAMAKAWA and Ichiro AOKI reporter: 黃薇蓉. Arthroppda 節肢動物門

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Keita KODAMA, Takamichi SHIMIZU, Takashi YAMAKAWA and Ichiro AOKI reporter: 黃薇蓉

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  1. Reproductive biology of the female Japanese mantis Shrimp Oratosquilla oratoria (Stomatopoda) in relation to changes in the seasonal pattern of larval occurrence in Tokyo Bay, Japan Keita KODAMA,Takamichi SHIMIZU,Takashi YAMAKAWA and Ichiro AOKI reporter:黃薇蓉

  2. Arthroppda 節肢動物門 Crustacea 甲殼亞門 Malacostraca 軟甲綱 Hoplocarida 掠蝦亞鋼 Stomatopda 口足目 Squilloidea 蝦蛄總科 Squillidae 蝦蛄科 Oratosquilla口蝦蛄屬 Oratosquilla oratoria 口蝦蛄

  3. INTORDUCTION • The Japanese mantis shrimpOratosquilla oratoria(de Haan) (Crustacea: Stomatopoda) is found onmuddy bottoms in coastal waters around Japan. • The catch ofO. oratoriafrom Tokyo Bay : the mid to the late 1980s > the early 1990s.

  4. INTORDUCTION • The hypothesis was examined: because the spawning season of large female shrimps around May has come to be delayed since the early 1990s, there is low larval abundancebefore July. • gonadosomatic index ( GSI ) • histological development of the ovary for each size class • size at first maturity • fecundity

  5. MATERIALS AND METHODS • Samples • Histological procedure • Reproductive cycle and size at first maturity • Fecundity • Larval data

  6. Samples • January to December in 2002. • 14549 female shrimps • 688 individuals (●) seven samplingstations for female Oratosquillaoratoriain Tokyo Bay, Japan.

  7. Samples • Body length • Body weight • Gonadal weight • GSI = GW/BW ×100%

  8. Histological procedure Fixing Dehydration 70-100% ethanol Embedding paraffin 10% formalin Staining Cutting 6µm hematoxylin–eosin

  9. Reproductive cycle and size at first maturity • Ovarian developmental stage and the mean GSI were investigated for the size classesthat could attain vitellogenic oocytes. • 7 ≤ BL <8 cm, 8≤BL <9 cm, 9 ≤ BL <10 cm, 10 ≤ BL <11 cm, 11 ≤ BL <12 cm, BL ≥ 12 cm. • Size at first maturity was defined as the smallest size class at which more than 50% of individuals attained vitellogenic oocytes in the ovary.

  10. Fecundity • Samples of a fixed ovary of approximately 3–30 mg were dissected for each individual of the ovary. • The following equation was used to estimate the fecundity of each individual: F=F s × GW/ GWs F : the estimated fecundity of an individual Fs:the number of oocytes in a sample GW:the total weight of the ovary GWs : the weight of the sample of the ovary

  11. Fecundity • Fecundity in relation to BL was estimated using the following equation: F(x) =ax x:BL in cm, F(x): the fecundity against BL a and b: constants b

  12. Larval data • May to October in 2002 • Oratosquilla oratoria have 11 larval • stages. • The smallest size class of larvae • was 0.9 ≤ CL < 1.1 mm, corresponding • to the third stage . (△ ) 15 sampling stationsfor the larvae in Tokyo Bay, Japan.

  13. RESULTS & DISCUSSION • Oogenesis • Developmental stage of ovary • Reproductive cycle and size at first maturity • Fecundity • Spawning and larval abundance

  14. Oogenesis

  15. Oogenesis • Oogenesis was divided into 10 stages: (1) Oogonium stage (2)Early chromatin nucleolus stage (3) Late chromatin nucleolus stage (4) Oil globule stage (5) Yolkless stage (6) Primary yolk granule stage (7) Secondary yolk granule stage (8) Pre-maturation stage (9) Maturation stage (10)Atretic stage Most female O. oratoria under rearing conditions spawn at night (K Kodama, 2002)

  16. Developmental stage of ovary Developmental stages

  17. Developmental stage of ovary

  18. Reproductive cycle and size at first maturity stage 1 immature stage 2 previtellogenesis stage 3 primary vitellogenesis stage 4 secondary vitellogenesis stage 5 maturation stage 6 spent Tokyo Bay in 2002

  19. Reproductive cycle and size at first maturity ( △) 25–49% ( ○) 50–74% ( ●) 75– 100%

  20. Reproductive cycle and size at first maturity • The size at first maturity, 7 ≤ BL < 8 cm, was smaller than that recorded in the mid 1980s. • The CPUE of O. oratoria in the 1990s fell dramatically to approximately one-fifth of that in the mid to late 1980s. • In addition, the annual catch of O. oratoria in Tokyo Bay was high in the mid to the late 1980s, followed by an abrupt decrease in the early 1990s, and the catch has since remained low. • The decrease in size at first maturity seems to be concurrent with that in the stock size.

  21. Fecundity 2.79 2 A total of 25 individuals, ranging from 7.1 cm to 13.9 cm BL, with ovaries at stage 4 were investigated for the estimation of fecundity. The relationship between body length x in cm and fecundity F(x) is given by F(x) = 58.4 x (r = 0.93, n = 25, P < 0.001) From this formula, the fecundity of shrimp of 8, 10, 12 and 14 cm BL was estimated to be 19300, 36000, 59900 and 92100 eggs, respectively.

  22. Fecundity b

  23. Spawning and larval abundance • Spawning season of O. oratoria in Tokyo Bay in 2002 lasted from April to September. • One possibility is that female shrimps thatdid notattain the minimum size at maturity in spring haveincreased their size to ≥10 cm BL by summer andexperience their first spawning in summer. • Another possibility is that large female shrimpshave two broods in a spawning season.

  24. Spawning and larval abundance • These results do not support the hypothesis that the decrease in larval abundance before July beginning in the early 1990s was caused by a delay in the spawning season of large female shrimps around May.

  25. Spawning and larval abundance • First, the mortality of the larvae occurring before July could be extremely high. • The larval abundance was investigated at the third stage, immediately after starting the pelagic phase, and, under rearing conditions, the mortality of the larvae was low until the fifth stage.

  26. Spawning and larval abundance • Second, the hatching rate of the eggs laid by large female shrimps in spring could be low. • Although the hatching rate of fertilized eggs of O. oratoria under rearing conditions was low, the reason for the low hatching rate and whether the hatching rate in the field is as low as in rearing conditions remain uncertain.

  27. Spawning and larval abundance • Third, a substantial decrease in the stock size of large female shrimps could result in decreased egg production in spring and low larval abundance before July.

  28. Spawning and larval abundance Nevertheless, the thirdpossibility seems to be a major determinant of thelow larval abundance before July, although theother two possibilities can not be excludedcompletely.

  29. Spawning and larval abundance • Undoubtedly, fishery regulation during thespawning season is required to enhance the resilienceof the stock size of O. oratoria. • In particular,regulation around the spawning peak in spring,during which most large female shrimps with highfecundity spawn, might be effective for recoveringlarval abundance before July.

  30. Thanks for your attention

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